Domain-specific syntax tagging in a functional information system

ABSTRACT

The invention relates to systems and methods using a logical data model for aggregating data entities in a functional information system supported upon a computing platform, and also for providing systems and methods for analyzing economic information using a functional coordinate system.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application hereby claims priority under 35 U.S.C. §119(e) to U.S.Provisional Application Ser. No. 61/801,959, entitled “Syntactic Taggingin a Domain-Specific Context,” and to U.S. Provisional Application Ser.No. 61/802,245, entitled “Domain-Specific Syntactic Tagging in aFunctional Information System,” both by inventor Rory Riggs and filed onMar. 15, 2013, the contents of which are herein incorporated byreference.

FIELD OF THE INVENTION

The invention relates to systems and methods using a logical data modelfor aggregating data entities in a functional information systemsupported upon a computing platform, and also for providing systems andmethods for analyzing economic information using a functional coordinatesystem.

BACKGROUND OF THE INVENTION

There exist numerous systems for storing data entities for subsequentretrieval. Typically, these systems take the form of an electronicdatabase. Electronic databases are available in numerous types, such asflat file or relational. A relational database is typically a collectionof data items organized as a set of formally described tables from whichdata can be accessed or reassembled in different ways without having toreorganize the database tables.

Information systems can be examined at different levels of abstraction,principally as a physical data model and as a logical data model. As anexample of a physical data model, a relational database managementsystem (RDBMS) can be implemented physically using, for example, anindexed file capability executing on an operating system. The RDBMSpresents a logical model to its user: one consisting of tables with rowsand columns, typically supporting SQL queries and amenable to techniquessuch as data normalization. While relational databases have provenuseful, there are significant limitations to this method of storingdata.

In particular, the logical data model does not capture semantic meaning.For example, a relational database table might store city names inmultiple rows in a first column and respective population values inmultiple rows in a second column. The bare fact that two records may beadjacent provides no information about the relationship between therecords. Thus, while useful information can be extracted from arelational database, there is additional semantic value that is notrepresented in these systems. This semantic information is notinherently captured or represented by existing relational databases.

Furthermore, prior art relational database systems are ill-suited tostoring information relating to taxonomies and anatomies. Taxonomies andanatomies are methods for describing a system in which an element'srelative and absolute location in the system provides information aboutthe element's specific role or function in the whole system. While thistype of information from a taxonomy or anatomy could be stored in anadditional field in a relational database, the relationship between thedatabase records still would not provide any information about therelationship between the data entities.

In another existing system, OLAP cubes allow for “spinning and slicing”(pivot table-like) manipulation of N-dimensional cubes of data, and theelements of the N dimensions can be organized as a hierarchy. However,OLAP cubes have several limitations. OLAP cubes are neither well suitedfor handling variable tree depths nor are they designed to navigate to acomponent within the N-cube space. Rather, OLAP cubes simply facilitateanalysis across the several dimensions. OLAP cubes are also not intendedto support sparse matrices where, at some levels, in some dimensions thedata is simply not there for valid reasons.

While semantic web technology (such as OWL, OPML, RDF etc.) canrepresent taxonomies and ontologies and is purposely designed to do so,its focus is on knowledge representation of an ad hoc nature andcreating relationships between such ad hoc knowledge. This capability isin part due to the semantic web's having been derived significantly fromartificial intelligence approaches to knowledge representation andrelationships (famously the “IS-A” relationship—[crimson is-a red] [redis-a color] [color is-a physical-attribute] allowing the conclusion thatcrimson is a physical-attribute). Notably, however, the semantic webdoes not readily enable navigation via multiple standardized, orderedcoordinates. Furthermore, these semantic web approaches do not attemptto implement or take advantage of domain-specific statistically relevantcategories in defining these standardized coordinates as an inherentpart of their technology.

The inability to derive semantic meaning from data structures becomesparticularly acute when prior art systems operate on unstructured data.While some taxonomies and anatomies have a fundamental data structure,other types of data may appear to be completely unstructured.

For example, there exist various economic taxonomies such as the GlobalIndustry Classification Standard (GICS) developed by MSCI and Standard &Poor's (S&P) for use by the global financial community. The GICSstructure consists of 10 sectors, 24 industry groups, 68 industries and154 sub-industries into which S&P has categorized all major publiccompanies. The system is similar to ICB (Industry ClassificationBenchmark), a classification structure maintained by Dow Jones Indexesand FTSE Group. This taxonomy, however, has certain limitations. Inparticular, it does not define relationships common to all companies.Consequently, a user cannot compare two companies' GICS classificationsto derive relevant meaning unless they share a common ancestor in thetaxonomy. While it allows for great granularity and differentiationbetween companies, it lacks standardized values for comparison, sincethe rules for being at one level in a group are unrelated to the rulesfor being at a corresponding level in another. Thus, comparisons acrossdisparate industries are not possible. Furthermore, the ten sectorstructure can be criticized as an arbitrary identification of tensectors; there is not necessarily a relationship between one sector andthe next. As a result, storing such data in a relational database tablecould not provide any additional semantic meaning because the originaldata entities did not have a consistent and uniform relationship amongthemselves.

Due to these types of limitations and others, no prior artclassification system has been based on clearly defined relationshipsbetween the constituent elements because there has not been anunderlying data model for the attributes on which that system is based.Additionally, because there has been no underlying model foreconomics—and even if there had been—there would be no suitable datastructure for representing the model.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 illustrates an example representation of semantic relationships.

FIG. 2 illustrates an example three-dimensional coordinate system.

FIGS. 3-1 and 3-2 illustrate an example syntax specification.

FIGS. 4-5 illustrate example activity wheels.

FIG. 6 illustrates example activities and resources.

FIG. 7 illustrates example activity phases and resources.

FIG. 8 illustrates example resources and processes.

FIG. 9 illustrates an example arrangement of resources.

FIG. 10 illustrates example relationships between operating and enablingresources.

FIG. 11 illustrates an example of organizational levels andrelationships between and among levels.

FIG. 12 illustrates example relationships between activities andresources.

DETAILED DESCRIPTION

In the following description of embodiments, reference is made to theaccompanying drawings that form a part hereof, and which show by way ofillustration specific embodiments of the claimed subject matter. It isto be understood that other embodiments may be used and that changes oralterations, such as structural changes, may be made. Such embodiments,changes or alterations are not necessarily departures from the scopewith respect to the intended claimed subject matter. While the stepsbelow may be presented in a certain order, in some cases the orderingmay be changed so that certain inputs are provided at different times orin a different order without changing the function of the systems andmethods described. The procedures described below could also be executedin different orders. Additionally, various steps that are describedbelow need not be performed in the order disclosed, and otherembodiments using alternative orderings of the steps could be readilyimplemented. In addition to being reordered, the steps could also bedecomposed into sub-computations with the same results.

Many problems cannot be adequately addressed simply by frequentlyissuing a static data query at points in time. This is particularly thecase when working, for example, with a high volume data stream. Newapproaches to data require reframing the data model. Instead of a seriesof conventional queries that return resulting data, there is a need forcontextual queries that enable the user to parse semantic componentsignifiers related to a plurality of different complex parts ofextremely complex systems. Data so represented and queried representsthe complexities of natural systems. An example is represented in FIG.1.

The inventive functional information system can be used to parse throughthese dense and complex data fields. To accomplish this, the functionalinformation system can subdivide each part, concept or idea into anordered set of fields, each of which have a defined syntax amongthemselves and with respect to the values that are used to characterizeeach signifier.

The inventive functional information system enables these comparativeanalytics for multiple domains, signifiers, and component values withinsignifiers across the entire domain of the functional informationsystem. Capabilities of a functional information system can includeparsing, identifying, studying, and comparing each part both absolutelyand within the context of the whole domain in which the part exists.

Fundamentals of a Functional Information System and Coordinates

The invention includes a logical data model for organizing data entitieswithin a given discipline in which the functional position of eachelement is identified with respect to the other elements. In order to dothis, the invention applies standardized values, called coordinateidentifiers, to tag various facets of each element in the domain. Thesecoordinate identifiers classify each facet or element in n-dimensionalspace. Once data entities are represented in the coordinate space, theordering of the coordinates enables referencing their semantic meaningbased on the locations of the data entities in the coordinate space. Italso enables comparison between different data entities along any of thedimensions of the functional information system.

As used herein, a complex system can be a network of heterogeneouscomponents that can interact nonlinearly and, as a whole, give rise toone or more emergent properties or specific outputs. In a complexsystem, the parts have a functional role in the emergent property orobject of the larger system. Systems can be considered to consist of acollection of component parts that fulfill both a role and function inthe operation of an overall system. Each of these component parts canhave functionally specific operating information related to theirspecific role, function and performance in the system in which theyexist. Processes for systemizing data entities related to parts in aspecific system using a systems database are described herein.

Together, through the functioning of these parts, the system as a wholehas functionality. The computerized system described herein enables thefunctional mapping of information related to any arbitrary complexsystem on a coordinate basis. The functional coordinate system describedherein is generally applicable to many domains associated with complexsystems including, for example, ecological systems, biological systems,social systems as well as mechanical systems. In one particular example,described in more detail below, the functional information system isapplied to economic systems. Similar techniques to those described couldbe used to extend the system to other domains.

A functional information system can be constructed using coordinateidentifiers for the location of components in the system. Location-basedcoordinate identifiers enable a functional information system that cancapture, store, manipulate, analyze, manage, and present all types offunctional and operating data for a whole system on acomponent-by-component basis. In addition, the functional informationsystem can aggregate coordinates into larger groupings, disaggregatelarger groupings into smaller groupings, or relate any coordinates thatshare common attributes. These operations can be performed in real time,past time, or projected time.

The functional information system described herein enables the use ofcoordinate-based systems to compare components of different systems thatotherwise would not be capable of ready comparison. The complex systemsmodeled may be related to analogous systems. For example, a business isa complex system, as is a human anatomy. Each of these examples has manyversions of a basic model. Each of these systems can be represented on acorresponding and analogous coordinate-based system. A coordinate systemcommon across all versions enables coordinate-by-coordinate comparisonand analysis.

For example, in economics, it is possible to have common coordinates forall cities, businesses or industries. The system described hereinenables a manager of any of these types of complex systems to comparecoordinate values to other examples of an analogous type of system, suchas an industry, business or city. Furthermore, in a system of systems inwhich systems on different levels use the same coordinate system,systems databases enable a user to compare differences between systemsthat are part of one overall system but exist on different levels withinthe overall system. Systems databases can be used to standardize thevocabulary across a whole system and all of its parts and activities. Asystems database can be used to provide a standardized and systematicbasis for inter- and intra-system analytics.

The functional information system described herein can operate on eachcomplex system as a functioning whole, while each component of thecomplex system can be considered to be a functional part of afunctioning whole. The functional information system can assign eachcomponent a coordinate-based identifier that locates a component in itsdomain-specific complex system. To represent source data entities in thefunctional information system, the data entities are assigned systemscoordinate values that relate to pre-defined coordinate locations in thedomain-specific system in which the data entities exist, the coordinatevalues being assigned to reflect the function or role of a facet of thedata entity in its domain. A systems database can be constructed usingone or more coordinate axes to tag the data entities in the database. Anexample three-dimensional coordinate system is illustrated in FIG. 2.Coordinate locations are relational values that are based on acoordinate system in which every coordinate can be described withrespect to a fixed reference point and to standard increments from thefixed reference point. Together, the fixed reference point and itsstandardized increments form a coordinate axis. All coordinates on theaxis reference either the fixed reference point or a standard incrementfrom the fixed reference point.

The coordinate system for complex systems can be implemented though thefunctional coordinate system described in more detail below. Thefunctional information system coordinates relate the functional role ofone component to the other components of the complex system. Thefunctional information system orders the heterogeneous components ofcomplex systems into a multi-dimensional functional coordinate system inwhich each coordinate point is the location of a specific functionalcomponent of a whole complex functioning system. The coordinates can beused to locate a functional component of a complex system inmulti-dimensional space in a functional coordinate system. Thecoordinate system described herein associates n-dimensional coordinateswith the functional role of a specific location in a specific complexsystem. Domain-specific data can be prepared for representation in thefunctional information system by decomposing systems into functionalcomponent facets. The resultant functional component facets can then bearranged into individual functional coordinate systems, which can thenbe arranged into a multi-dimensional coordinate system.

The functional information system can represent data in a coordinatesystem using multi-dimensional constructs using any integer number ofdimensions. While some embodiments, as described below, can include fourdimensions (e.g., subject resource, activity, direct object resource,indirect object resource), a generalized functional information systemcan express any integer number of multiple dimensions. In someembodiments, an additional dimension can be added to represent differentlevels. For a given functional information system, the number ofdimensions is determined and fixed prior to applying the functionalinformation system to structure data.

Storing and Extracting Semantic Meaning from the Functional InformationSystem

The coordinates used in the coordinate system are, in and of themselves,semantically meaningful. This characteristic, in combination withmultiple dimensions, forms the basis for an essential distinction fromtaxonomies/ontologies and related systems, which, while potentiallyattaching meaning to a numbered node within a hierarchy, do not reflectmultiple dimensions carrying semantic meaning. The semantic meaning canbe assigned either manually or by automated processing.

As a result of the data entities having coordinate values, a data entityin the systems database can be characterized as having semantic value.Within a given dimension, this value can be comprised of: 1) an absolutevalue based on its coordinate position; and/or 2) a relative value basedon its relative position to the other individual elements that exist inthe systems. Additionally, each dimension of the functional informationsystem has a semantic value; data entities thus have additional semanticvalue derived from the dimension in which the coordinate exists. Dataentities that have common coordinate values will have common absoluteand relative values. Thus, coordinates can have both absolute meaningbased on the meaning assigned to that coordinate point and relativemeaning based on the meaning defined by the difference between thatcoordinate point and any adjacent coordinate points.

The coordinates can be semantically meaningful and have semanticrelationships. These coordinate tags provide specific relational systemssemantics descriptive of each element relative to the other elements andthe overall system. As a result, the systems database can be used foroperations on systems semantics that relate to the specific systemcharacterized by the specific coordinate systems.

Because the coordinate points are defined semantically, they are boundby predetermined semantic rules. As a result, a rules-based coordinatesystem is constructed. The rules relate to how to traverse the set. In afunctional coordinate system, the increments are rules-based. The rulestell the absolute value and provide location relative to other absolutevalues. In all of these systems, there is a base value from which theothers are referenced. System may be modeled as a coordinate systemhaving axes, but are not required to be modeled as such.

Systems databases can be used to provide data structure by assigningsystems coordinates to unstructured elements. The assigned coordinatesprovide a semantic basis for: 1) an element's specific role or functionin a whole system, 2) matching or comparing the role or function of oneelement to the role or function of another element, 3) tracking theevolution of an element over time both absolutely as well as relative toother elements in the system, and/or 4) comparing similarities ordifferences (historical, current or future) of one system to anothersystem.

Within this model, the organization of information can be standardized.Each entry in the systems database can specify qualitative informationrelated to its role and function in the overall system. In addition,each entry can specify quantitative measurements that are used tomeasure its functional requirements and functional performance. Thequantitative information entries can represent at least three types ofquantitative information:

1) Part specific information,

2) Relational information that links the part to other parts with whichit interacts, and

3) Relational information that links the part to the overall system ofwhich it is a part.

As non-limiting examples, the first element (part specific information)can contain the critical operating information and can be comparedtemporally to track and predict performance. The second element(relational information that links the part to other parts with which itinteracts) tracks the balance of the specific part within the operationof the system itself. The third element (relational information thatlinks the part to the overall system of which it is a part) tracks theoperation relative to the system as a whole and all its other parts.Together, these three information modules can provide operationalinformation relative to each individual part as well as each part's roleand operations within the larger system.

Coordinate-Based Identifiers Representing Cardinal Identifiers

A pre-defined functional arrangement provides a primary building blockfor a functional coordinate system. A functional arrangement can beconverted into a functional coordinate system by defining a fixedreference point and assigning coordinate identifiers to each of thecomponents of the functional arrangement. In some embodiments, thecoordinates in the functional information system can representfunctional arrangements of domain-specific data entities.

A functional arrangement is a functional sub-grouping of a set ofinterconnected functional activities (or objects) in which eachsub-group fulfills a defined functional role as part of a whole systemand the internal order of the functional sub-grouping is derived fromthe temporal or physical sequences in which the sub-groups perform theseactivities. A functional sub-group can possess a unique functional valuethat, together with the other sequential functional groups, enable awhole function value associated with the functional arrangement. Eachsequential location is specified relative to a fixed reference point,such as the first sub-grouping or the last sub-grouping of the set. Assuch, each functional arrangement defines a specific functionalcoordinate system.

Functional Coordinate Representation (Regarding N-Tuples and DotNotation)

The systems and methods described herein can represent coordinate pointsand cardinal identifiers using n-tuples and dot notation. This notationcaptures the specific notion of ordered coordinates as used in thefunctional information system. N-tuples are commonly illustrated byusing small sets of ordered symbols, often alphabetic or numeric.N-tuples are also inherently discrete (being a set of elements). Ann-tuple can be an ordered set of n symbols. For example, the sets (1, 2,3, 4) and (A, B, C, D) are both 4-tuples.

The n-tuples can be represented in n-dimensional coordinate space.Furthermore, each dimension of the coordinate system can be expressed asone or more n-tuples, which are ordered (consistent with mathematicaldefinition of N-tuples); typically n-tuples in an FIS consist of alphaor numeric symbol sets.

Each n-tuple can have semantic meaning within the n-tuple set and suchsemantic meaning is of a level of generality comparable to its peerswithin the n-tuple.

Each n-tuple can also express a hierarchical semantic relationship inrelation to other n-tuples of the dimension. This expression representssuccessive specialization. For example, (2,2,1) and (2,2,3) can befurther specializations of the partial coordinate (2,2).

Application of Functional Information Systems to HierarchicalClassifications

The functional information system can also be used to representhierarchical classification systems. An information system forcharacterizing a specific system typically organizes the operatinginformation in a hierarchical manner, with the ultimate parent being thesystem itself and each lower level grouping relating to ever-smallersub-systems of the parent. The organization of the hierarchy isgenerally anatomically organized, such that the upper-most groupingreflects the major sub-systems and each lower level grouping is asub-system of the anatomical parent. By definition, in a system thereexist a finite number of upper-level sub-systems, each upper-levelsub-system having a finite number of sub-systems. For example,organizational charts for a business and anatomies in biology aretypically organized in this manner.

As a non-limiting example, hierarchical levels can include GlobalEconomic Systems, Sub-Global Economic Systems, Industrial Groups,Enterprise, Departments, Work Groups, and Labor. In this example, agiven enterprise or department could be associated with a specificcoordinate in the coordinate system. For example, a given enterprise ordepartment could be associated with a specific coordinate in thecoordinate system.

The functional information system can support an arbitrary number ofhierarchical classifications to which the coordinate system is appliedfor any given domain. As a result, the functional information systemapplies a multi-dimensional, semantic coordinate system to one or morehierarchical classifications. As an alternative example, biologicalsystems can be represented by hierarchies reflecting both phylogeny(species, sub-species etc.) and anatomy/systems biology, with a singlehuman skin cell sharing a portion of its sub-coordinates (nucleus, cellwall components) with a single cell amoeba, despite the single celloccupying very different positions with respect to the two hierarchies.

In a hierarchical coordinate-based information system, a coordinateidentifier can identify a sub-set of the whole system with specificattributes related to its coordinate sub-set. All components assigned toa common coordinate sub-set can share component-specific attributesrelated to the attributes of the coordinate sub-set. In amulti-dimensional coordinate system, components assigned to a locationin a system will share attributes of multiple intersecting coordinatesub-sets. This capability results from the use of coordinate-basedidentifiers where each coordinate value is a class value where the classis defined as the specific coordinate-based sub-set. Each location hasattributes related to each of its coordinate identifiers related to itsspecific location in n-dimensional coordinate space. The attributes foreach point reflect each of these sub-set coordinate values and can beorganized using any one or more classes of coordinate sub-sets. A usercan examine a specific location in a system or examine a broadaggregation of locations using multiple coordinate values.

The coordinate-based systems can be used to compare analogous componentsof analogous systems. The system described herein can support manymembers in a grouping of analogous complex systems and thereby enablecomparability of analogous components of complex systems of the sametype.

System Implementation in Logical Data Models

The invention includes a database system and related data model aimed atsupporting complex queries on complex interrelated data feeds.

As an initial matter, it is helpful to distinguish between a logicaldata model/database and a physical data model/database. In someembodiments, the logical models and databases comprising the coordinatesdescribed herein can be implemented in a relational database. Thesystems and methods described herein can include a translation modulewhich reads and writes information using an RDBMS data model and relatednavigation (tables, SQL) associated with relational databases andpresents the information to a user using coordinates representingfunctional components.

According to the present invention, a multi-dimensional database can berepresented as a relational schema in the relational database. Themulti-dimensional database can have one or more dimensions having one ormore members. Each value in the multi-dimensional database is identifiedby the intersection of one member from each dimension.

The system described herein can be implemented in a multi-dimensionaldatabase. Generally, the multi-dimensional database is arranged as amulti-dimensional array, so that every data item is located and accessedbased on the intersection of the members which define that item. Thearray comprises a group of data cells arranged by the dimensions of thedata. For example, a spreadsheet exemplifies a two-dimensional arraywith the data cells arranged in rows and columns, each being adimension. A three-dimensional array can be visualized as a cube witheach dimension forming an edge.

One example application of the logical data model can be applied to theclassification of companies. As described above, GICS provides ahierarchical classification of companies without reference to anunderlying economic system.

Syntax for Representing the Logical Data Model

The functional information system data model utilizes a common syntaxthat is generalizable and comparable across many data points that areassociated with this common syntax. The syntax can capture a grammarwhich, along with a lexicon embodied in the coordinate system, givesrise to greater semantic functionality.

In some embodiments, the lexicon can be constructed from domain-specificfunctional arrangements, while the syntactic rules characterize thedimensions of the functional information system.

A Syntax for a Generalized System

The functional information system data model can utilize a syntax thatis imposed on the coordinate system. While a subject, activity, objectform proves useful in many domains, such syntax can be of any form.Thus, a locus can be based generally on a syntax imposed on thefunctional information system coordinates in combination with othersyntactic and/or semantic elements (such as, for example, Product,Intermediary/Customer, etc., as discussed below.)

The loci can be combined to form a bar code. In some embodiments, suchas those described in more detail below, the bar code can be a 15-tupleof loci. Each of the 15 coordinates of this tuple can be filled withvalues drawn from functional information system coordinates. Additionalgeneralizations are possible. For example, a bar code can be defined asa group of field and coordinate pairs where each pair as a correspondinglocus. This type of bar code allows creation of a different bar code fordifferent types of entities.

The functional information system creates coordinates, loci, and barcodes based on values from underlying sets which are then combinedaccording to certain syntactic rules, as described in more detail below.In some embodiments, these sets may be functional arrangements. Thevalues of the elements of these underlying sets have semantic meaning.These values can have meaning both inherently with how they relate tothe other values and the set as a whole.

The bar code system disclosed herein can be utilized in conjunction withsyntactic tagging systems and can be used in the creation of a relateddictionary as well as domain-specific syntactic structures that havedomain-specific names. The related discipline of syntactic tags can beused to create the component elements. A bar code can be created bycombining multiple component elements selected from one or more specificdomains.

In any domain, the identification of any data entity involvesidentifying a specific position in a domain and relating it to otherpositions. A bar code can be used to link domain-specific syntacticpositions to other syntactic positions in a domain through a system ofnested syntactic positions thereby enabling identification and naming ofcomplex domain-specific structures. For example, a car, a steel girder,a barber, and a semi-conductor manufacturer can be identified using thebar code structure by linking together related domain-specific positions(sometimes in multiple domains on multiple levels). This ability to namedomain-specific complex parts of complex systems is enabled by the barcode.

Autoclassification can be used in connection with the bar code. Adictionary of domain-specific terms can be created, wherein the termsare defined syntactically through the bar code. Then algorithms can becreated that match these domain-specific, syntactically-defined, termsto existing terms in a domain and, thereby, create a domain-specificfunctional information system on an automated basis. These methods canbe interrelated by employing syntactic tagging technology in the barcode method, and employing the bar code method in the autoclassificationmethod. These methods can be used in a wide variety of disciplines andare not necessarily unique to any particular field of study. Rather,they may be broadly applicable to any domain. For example, in many ofthe scientific domains, the bar code can be used to provide a pathway toa unified record system for the domain-specific parts of their domainthat is both dynamic and relational.

A Domain-Specific Syntax

A domain-specific syntax can be defined and created by the methoddescribed below.

A set of rules can be created that can be used to 1) generate validsyntactic tags; or 2) determine if a syntactic tag is valid or not.

These rules can be expressed in BNF notation, or an equivalent notation.

The valid expressions (or sub-expressions) in the syntax that have arange of potential values (in the BNF, expressions that have multipleoptions separated by “or”s) and can have properties including:

1) They describe a dimension in a discrete multidimensional spaceconsisting of the dimensions associated with all such elements. Theremay be spaces in the bar code where a specified range of acceptablevalues (for example, in the enterprise locus resource category space),A, B, C, D, E, or F can be placed. So {A, . . . , F} describes adimension in a discrete multidimensional space. Another exampledimension could be resource stage, taking on values 1 to 4, orsub-stage, with values i to iii, or in the activities, as described inmore detail below.

2) They can be hierarchically organized, so the dimension describedabove consists of regions and successive subregions within themulti-dimensional space. Thus, the activity and resource values can besubdivided.

A Syntax for an Economic System

As discussed above, elements of the underlying sets can have semanticvalue expressed as relationships between the elements. As a non-limitingexample, the order of the underlying sets gives rise to the orderrelationship, which informs about the semantic meaning “which thing camefirst”.

The systems described herein can include one or more dimensions, eachdimension comprising an axis that characterizes a facet of thedomain-specific data along a functional arrangement. For example, oneaxis can be the “activity” axis, which can be considered to be anordered set of 36 activities, for example {1.1.1, 1.1.2, . . . , 4.3.3},under the ordering 1.1.1<1.1.2 < . . . <4.3.3. Another axis can be usedto describe “resource” categories, {A, B, C, D, E, F}, under theordering A< . . . <F. The system can also include resource stage andsubstage axes, which are {1, 2, 3, 4} and {i, ii, iii} under theorderings 1<2<3<4 and i<ii<iii, respectively.

In each axis, there may be defined relationships between the elements.One such type of relationship is order. These relationships can carrysemantic value, allowing data entities to be meaningfully compared.

Given these axes, coordinate 10-tuples can be formed as<resource-category, resource-stage, resource-substage, activity,resource-category, resource-stage, resource-substage, resouce-category,resource-stage, resource-substage>. The first three coordinates can bereferred to as the “subject resource”, the next as the “activity” or“verb”, the next 3 as the “object resource”, and the final three as the“indirect object”. In some embodiments, described in more detail below,the syntax can capture <subject resource><activity><object resource> inthe syntax. However, these elements are not required.

Similar to the way that the activity set can be considered to be {1.1.1,1.1.2, 1.1.3, . . . }, the resource, resource-stage andresource-stage-value sets could be combined into a single set {Ali,A1ii, A1ii, A2i . . . }. This might make sense if there are additionalrules on how any tuples are constructed in that not all combinations arevalid, i.e. (F, 1, ii).

Alternatively, activities could be considered as 3-tuples taken from 2separate ordered sets, one being {1,2,3,4} and the other being {1,2,3},where each activity is dot notation of a 3-tuple <activity-phase,activity-division, activity-department>, with phase coming from thefirst activity axis and division and department from the second axis.The activity value in the coordinate is then a 3-tuple (elements oftuples can be other tuples). The activity can be considered as beingdrawn from an ordered set of 36 activities, and the coordinates as10-tuples. Coordinates could also be considered to be 12-tuples, insteadof 10-tuples, with 3 values for activity instead of just 1.

Loci can then be formed as tuples of coordinates plus contextualmarkers. Contextual markers can be configured to appear based on thelocus being queried. Similarly, some loci will not have subjectresources or indirect objects. Provisions can be made for div and thedifferent F stages/substages, as described in more detail below. A locuscan take on the structure of some n-tuple (coordinate value, marker 1, .. . , marker m) with the coordinate value being a 10-tuple as discussedabove followed by m markers, each drawn from a finite set of permissiblemarkers.

In one example embodiment, bar codes can be formed as 15-tuples of loci:(enterprise locus, integration locus, first intermediary locus, secondintermediary locus, customer subordinate resource locus, customer finalresource locus, customer work group locus, customer department locus,customer enterprise locus, parallel customer locus, customer of customersubordinate resource, customer of customer final resource, customer ofcustomer work group locus, customer of customer department locus, andcustomer of customer enterprise locus). These embodiments can include anexpanded number of axes used to form these loci or separately definedschema for each locus instead of just one general locus schema.

The relationships expressed by the syntax can include, but are notlimited to, order, subdivisions/successive specialization,pre/central/post, complementary, nodal/connecting, and sublevel/level. Asummary of selected relationships is provided below.

Activity Relationships

Order: 1.1.1<1.1.2< . . . <4.3.3. This indicates, in a given cycle, whatactivity happens before another. In the language of cardinalidentifiers, the lower-valued activity is required to take place beforethe higher-valued one can.

Subdivisions/Successive Specialization: 1.1.1, 1.1.2, and 1.1.3 sharethe “1.1” property. Indeed, all a.b.1, a.b.2, and a.b.3 are related forany fixed values a and b. Similarly, all a.1.*, a.2.*, and a.3.* share aproperty for any fixed value a, and any value *. (That is, all 9activities in phase 1, from 1.1.1 to 1.3.3, share some property of theparent phase). This relationship can express nearness. This relationshipis also useful for higher level analysis without unnecessary detail,i.e. consider only 12 activities, suppressing the 3rd level ofgranularity.

Pre/Central/Post: All*.*.1 activities are share a common characteristicof “pre-ness”, for any values of *. The value of “1” can be used toindicate “pre”. Similarly, all *.*.2s are related (having a“central-ness” attribute), and all *.*.3s (“post-ness”). Similarly, at ahigher level, there are relationships between the *.1.*s, as well as the*.2.*s and *.3.*s.

Complementary: Activities “across” from each other are related. That is,1.1.1 and 3.1.1, 1.2.2 and 3.2.2, 2.2.2 and 4.2.2, etc. share at leastsome characteristics.

Nodal/Connecting: Moving through the set in order, activities alternatebetween being “nodal” and “connecting”, which have semantic meaning1.1.1, 1.1.3, 1.2.2, . . . , and 4.3.2 (all activities wheresum-of-digits is odd) are all connecting activities; 1.1.2, 1.2.1, . . ., 4.3.3 (sum-of-digits even) are nodal.

Resource Relationships

Order: Within the levels/sublevels, there is an order: 1i<1ii<1iii<2i< .. . <4iii. The resource categories, A<B< . . . <E, can also be ordered.Those can be treated lexicographically, so A1i< . . . <A4iii<B1i< . . .<B4iii< . . . <E4iii. F can be considered separately.

Subdivision: All abi, abii, and abiii activities are related, for anyfixed values a and b. Similarly, all a1*, a2*, a3*, and a4* are related,for fixed a and any *. This is analogous to the subdivision relationshipin activities.

Sublevel/Level: Across all resource categories (A-E), and all levels(1-4), the individual sublevels (i-iii) are related. That is, there is arelationship between all **i resources (sublevel i has semantic value).Similarly, across all resource categories and regardless of sublevel,the level has some inherent meaning (i.e., all level 1 resources share aproperty, all level 2 resources, etc.) This is analogous topre/central/post.

The relationships described above can also be described using a formalframework:

Activity Relationships

Order: {(a.b.c, d.e.f) such that (a<d) or (a=d and b<e) or (a=d and b=eand c<f)}

Subdivision:

-   -   Department level: {(a.b.c, d.e.f) such that a=d and b=e}    -   Division level: {(a.b.c, d.e.f) such that a=d}

Pre/central/post:

-   -   Department level: {(a.b.c, d.e.f) such that c=f}    -   Division level: {(a.b.c, d.e.f) such that b=e}    -   Both: {(a.b.c, d.e.f) such that b=e and c=f}

Complementary: {(a.b.c, d.e.f.) such that a+d is even, b=e, c=f}

Nodal/Connecting: Nodal={(a.b.c, d.e.f) such that a+b+c and d+e+f areboth even}; Connecting=not nodal={(a.b.c, d.e.f) such that a+b+c andd+e+f are both odd}

Resource Relationships

Order: {(abc, def) such that (a<d) or (a=d and b<e) or (a=b and d=e andc<f)} where the orderings on the resource categories and stages arenatural, i.e. A< . . . <E, i<ii<iii.

Subdivision:

-   -   Sublevel: {(abc, def) such that a=d, b=e}    -   Level: {(abc, def) such that a=d}

Level/Sublevel

-   -   Sublevel: {(abc, def) such that c=f}    -   Level: {(abc, def) such that b=e}    -   Both: {(abc, def) such that b=e and c=f}

Syntax Notation

As a non-limiting example, the various syntax expressions of locuscoordinates described herein can be expressible in BNF (Backus NormalForm or Backus-Naur Form) or similar techniques for expressingcontext-free grammars, such as van Wijngaarden form. As such, the syntaxcan be fully generalizable. As a non-limiting example, the syntax can beused to provide successive definitions of coordinates, locus, loci andgeneralized abstractions for the concepts of levels and domains in anydiscipline represented in the functional information system, includingthose relating to economics and business.

The syntax specification can be a set of derivation rules, written as<symbol>::=_expression_ where <symbol> is a nonterminal, and the_expression_ consists of one or more sequences of symbols; moresequences are separated by the vertical bar, ‘|’, indicating a choice,the whole being a possible substitution for the symbol on the left.Symbols that never appear on a left side are terminals. On the otherhand, symbols that appear on a left side are non-terminals and arealways enclosed between the pair < >. The ‘::=’ means that the symbol onthe left must be replaced with the expression on the right.

An example using some of the constructs is provided in FIGS. 3-1 and3-2.

In some embodiments, the syntax can be defined using XML or anothermeans of description.

System Implementation in Physical Data Models

The systems and methods described herein can be implemented using anynumber of physical data models. In one example embodiment, an RDBMS canbe used. In those embodiments, tables in the RDBMS can include columnsthat represent coordinates.

In the case of economic systems, data representing companies, products,etc. can be stored in tables in the RDBMS. The tables can havepre-defined relationships between them. The tables can also haveadjuncts associated with the coordinates.

Using the RDBMS, searches can be executed for common coordinates.

An example table for use with economic systems is illustrated below.

TABLE 2 Entity

When a record is created in Table 1, it employs the Entity ID that iscreated by the insert operation on table 2.

Any other relational database could be used, such as NoSQL, that doesnot follow a fixed schema. Tables could be bridged across multiplemachines. Using NoSQL, the system could be implemented in one table.

Access, Retrieval, and Analysis Capabilities Enabled by the FunctionalInformation System

The functional information system enables a range of novel capabilitiesarising from the combination of multiple dimensions that capturesemantic meaning. These capabilities are further facilitated by othercharacteristics of the system, such as the fact that the coordinatescomprise ordered N-tuples which can describe successive specialization(among other features).

Contextual queries enable the user to parse semantic componentsignifiers related to plurality of different complex parts of extremelycomplex systems. Data so represented and queried represents thecomplexities of natural systems.

Access, retrieval, and analysis can be performed based on the followingrelationships deriving from the coordinate representation of the dataentities:

1. degree of difference,

2. successive details (drill down analysis),

3. functional relationships based on the semantics of the coordinates,and/or

4. same, similar, roughly similar (possibly across levels, for example,in economic systems, transportation companies vs. transportationfunctions of a department),

The system supports notions of functional equivalence acrossrepresentations of dissimilar real world domains by enabling differentcoordinate systems to be related to one another. For example,accumulated energy principles can be related across both biological andeconomic systems within the system. As another example, a geographiccoordinate system and a social graph coordinate system can be relatedvia mobile location to provide a useful social service system.

The functional information system supports interrelationships betweensimilar domains based on the identification of multiple fixed points incommon between the coordinate systems for those domains. For example,functional aspects of systems biology can be linked to human biologicalsystems.

User Interface Embodiments Enabled by the Coordinate System

Because the coordinate system is ordered, it can be mapped ontosimilarly ordered user interface expressions. In the economics/businessexpression of the system described below, this mapping can take the formof mapping the coordinates into the color spectrum, which itself isordered (though color is continuous, so the functional informationsystem adopts discrete shades as the basis for the mapping). See alsomatrix/tree representations of information/data as examples.

A Functional Information Systems (FIS) for Economic Systems

As described above, a complex system can be represented in thefunctional information system once the base information is translatedinto a functional coordinate system. These generalized rules describedabove for the organization information systems for systems can beapplied in a wide range of disciplines, including human anatomy andbusiness. An anatomy defines a finite number of systems that are allconnected, having absolutes, operational connections and overallrelationship. Any system that is based on an underlying anatomy havingthese characteristics can be represented using these methods.

The architecture can be used to provide a multi-dimensional coordinatesystem that associates, or tags, each of the parts of a system accordingto their role and functional location in the overall system. Thiscoordinate system creates a system of general systems markers. While atypical coordinate system can only be used to map a physical location intwo-dimensional space, the systems markers describe points on afunctional map based on characteristics such as the order of occurrenceand the type of physical parts required when performing a specificfunction at a specific functional location. This functional coordinatesystem uses fixed reference points and standardized increments fromthese reference points to characterize the system markers.

The approach described below uses the mapping of economic information asthe practical implementation of the generalized coordinate-basedinformation system described above. Economics as a domain does not havea generally accepted model for the organization of its parts. Theapplication of the FIS described above to an economic system illustratesboth the operation of the FIS as well as how different domains could usethe methodology to develop a coordinate-based information system. Inaddition, it illustrates how adopting a coordinate-based system for adomain of study fundamentally changes the information systems used bythe domain.

It creates the possibility of having common coordinates for all cities,businesses or industries. A manager of any of these analogous types ofcomplex systems could compare coordinate values to other examples ofanalogous systems such as an industry, business or city. Among otherthings, it would enable transparency across systems, real-timecomparative analysis and optimization models for any type of economicsystem. This would be true of any domain that adopted a functionalcoordinate system.

In many domains, like economics, there does not exist a structural modelof an underlying system. This means that there is also no structuralmodel for the information related to these systems. It is the structuralmodels for underlying systems that provide structural models for theinformation systems related to the underlying system. The functionalinformation system provides a tool for these domains to developcoordinate-based systems that could then be modeled and examined frommany different aspects.

For example, domains that rely on geographic information benefit fromthe coordinate-based infrastructure associated with geo-coordinates.These domains have a tremendous number of tools available to thembecause of the GIS systems enabled by these coordinates. All of thesetools would also be available to domains with functional coordinatesystems.

The systems and methods described herein can be used to classify thebusiness attributes of companies according to a standardized economicmodel. The classification system described herein can be rules-based.The systems and methods for structuring data include a language whichsyntactically integrates coded nouns (resources) and verbs (activities).The nouns are coded and the verbs are coded and, as a result, sentencesare coded, resulting in a classification language based on syntacticallyordered coded words. A graphical illustration of this arrangement ispresented in FIG. 1.

The syntactically ordered coded words are coordinates in the system forstructuring data. As discussed in more detail below, a bar code datastructure can be used to organize the coordinates and theirintersections into coordinate groups. The bar codes enable parts of aneconomy with shared coordinates to be linked. A representation of anexample bar code structure is illustrated in FIGS. 3-1 and 3-2.

The bar codes contain information that enables viewing each companyas: 1) a supplier; 2) a customer; 3) a product; or 4) as one of severaldictionary terms. The ability to have a syntactical organization ofthese many standardized values contained within a single classificationtool is unique to the approach described herein.

The analysis of an economic system, and its representation in a systemsdatabase, begins with identifying the component parts of the system.Resources and activities are discussed first.

Resources

All objects used in an economy can be classified in one of six resourcecategories: information (e.g., knowledge and ideas), capital (e.g.,currency and finances), energy (e.g., fuel and food), labor (e.g.,collective, work groups), real estate (e.g., facilities and shelter),and tools (e.g., clothing and equipment). The tools, information andreal estate can be considered to be operating resources, and the labor,energy, and capital can be considered to be enabling resources.

The resources can be associated with a corresponding letter. As anon-limiting example:

A. Real estate

B. Tools

C. Information

D. Capital

E. Energy

F. Labor

These resources form a functional arrangement of economic resources.FIG. 9 illustrates an example arrangement of resources.

Activities

As used herein, activities are the actions which resources perform onother resources. Every action which takes place in the economy can beclassified according to a set of standardized activities.

Activities can be considered to be part of a product cycle or a moneycycle. The product and money cycles can each be composed of an inputphase and an output phase. This results in four separate phases: aninput product phase (for purchasing and providing all inputs necessaryto produce the product), an output product phase (for producing theproduct), an input money phase (for selling the product and earningmoney for future operations), and an output money phase (for deciding onhow to use this money).

Each of the four phases can be further subdivided into three activitiesincluding pre, central, and post activities. These activities include:

1. Input Product Phase

1.1 Procurement

1.2 Transportation

1.3 Infrastructure

2. Output Product Phase

2.1 Product Design

2.2 Production

2.3 Quality Control

3. Input Money Phase

3.1 Sales

3.2 Money Transfer

3.3 Financing

4. Output Money Phase

4.1 Investment Design

4.2 Management

4.3 Budgeting

These 12 activities are illustrated mapped onto an activity wheel inFIG. 4. A company can be considered to perform any or all of the 12activities on an object resource. FIG. 12 illustrates the relationshipsbetween activities and resources across multiple loci.

In some embodiments, every activity may always be able to be furthersubdivided into three activities including pre, central, and postactivities. Thus the 12 activities can be thought of as 36 activities,as illustrated in FIG. 5, or as 108. In some embodiments, thissubdivision is infinitely possible.

These activities form a functional arrangement of economic actions.

The Enterprise Locus

As illustrated in FIG. 6, a locus can comprise an activity and itsobject resource. As described above, there can be, for example, sixcategories of resources. The intersection of an activity with its objectforms a coordinate on a grid. An example of such a grid is illustratedin FIG. 7, showing four activity phases operative on six categories ofresources.

A company can be classified by the activity in which it produces itsproduct, and the object resource of that activity. More generally, thisactivity is the job or function which the company performs in theeconomy.

A categorized company can be associated with an enterprise locus. Theenterprise locus of a company can comprise 1) the activity which thecompany performs, and 2) the object resource of the activity. Forexample, a company, such as an airline, that transports people could beclassified as a “1.2 F”. An auto manufacturer could be classified as a“2.2 B” because it is in the production of equipment. This arrangementcan be considered to be describing an activity and a direct object.

In some cases, for some companies, the output resulting from theactivity performed is information, which is in turn used for anotherresource. For example, asset managers do not typically directly interactwith the money which their clients provide. Instead, asset managersproduce the information which governs how this money will be invested.These types of companies can be characterized by indicating that thedirect object is information, and the indirect object is the resourcefor which the information is used. This arrangement can be considered tobe describing an activity, a direct object, and an indirect object. Forexample, an educational institution may be characterized as a “2.1 C-F”because it educates people using information.

According to the model described herein, activities are performed byusing resources. As a result, the complete syntax for a locus can bestated as subject resource-activity-direct object-indirect object.Subject resources can be considered to act on object resources. Forexample, a company involved in electrical parts distribution could becharacterized as a “B-3.1-B” while an internet retailer of consumergoods could be characterized as a “C-3.1-Div” (where “div” indicatesdiversified).

The enterprise locus structure described above of encoding based on anactivity, a direct object, and an indirect object, can be used toclassify more than the enterprise of a specific company. The same locusstructure can be used to classify numerous additional attributes.

The Customer Locus

The customer locus can be used where a company produces or provides aproduct which is used by the company's customer. For example, anarchitect may produce a blueprint which is used by companies whichdevelop real estate. The production of the blue print by the enterprisemay be encoded as a “2.1 A-C” and the customer may be encoded as a “2.2A”.

Intermediary Locus and Customer of Customer Locus

A company can also be represented by additional loci. For example, inaddition to an enterprise locus and a customer locus, a company can berepresented by an intermediary locus and a customer of customer locus.The intermediary locus can be used to classify an intermediary thatenables the company to provide its product to its customer. The customerof customer locus can be used to classify the customer of the customer.All of the loci used in the system can include some or all of a subjectresource (if applicable), activity, direct object resource, and indirectobject resource (if the direct object is information).

Product Locus

A product produced by a company can be characterized using the samelocus data structures, including some or all of a subject resource (ifapplicable), activity, direct object resource, and indirect objectresource (if applicable). A company can be considered to provide one ofthree types of products: 1) a resource component, 2) a final resource,or 3) an outsourced activity.

Levels

A company can be represented using four levels which define the degreeof organization complexity within the operations of the company. Thelevels can include: company-level, internal activity-level (work groupsand departments), final resource level, and subordinate resource level.Because products are not companies, but rather used in the operations ofcompanies (and consumers), products are used at either the subordinateresource, final resource, or internal activity level. FIG. 11illustrates an example of organizational levels and relationshipsbetween and among levels.

Subordinate resources are considered to be stage 1, 2, or 3 resourcesand are represented by the syntax of: subject resource-activity-objectresource. For example, an airplane engine would be encoded as“B3-2.2-E4”. Final resources are considered to be level 4 resources andare represented by the syntax of: subject resource-activity-objectresource. For example, an airplane would be encoded as “B4 1.2 F”.

At the work group and departmental level, companies which do nottransfer ownership of a resource from themselves to their customers, butwhich instead perform one of these activities on their customers'behalf, provide an activity-product. The syntax for encodingactivity-products can be the same as for companies: optional subjectresource (only required for certain activities, including but notlimited to 1.2 or 3.1)-activity -direct object-output object. Forexample, transportation activity using the airplane could be encoded as“(B4) 1.2 F”.

The levels within a company can be hierarchically related andlower-levels resources and activities can be used as part of theoperations of higher-level resources and activities. For example: Acompany may manufacture car engines which are used within a car. Theengine produces final energy within the car. The car manufacturerincorporates the engine into a car. The car is used to transport people.People are the customers of the car. They use the car in theirtransportation activity.

Classification Systems Employed

The parameters discussed above and the information processed by thesystems and methods described herein can be represented in variousdifferent types of classification systems. Four types of classificationsystems are presented below:

Anatomic classification systems which classify every element of a systemas performing a function which contributes to and can be related to thefunction of the whole system;

Coordinate classification systems which assign attributes to all theelements of a system in order to determine the relative positions andorder of those elements in the system;

Anatomic coordinate classification systems which are anatomic systemswhich are defined using coordinate values; and

Word classification systems which group words based on linguisticcategories such as nouns and verbs into expressions and sentences.

Based on these definitions, these classification systems can be appliedat the four levels of classification: 1) resources, stages andactivities; 2) loci; 3) fields; and 4) the entire company classificationsystem.

In this example, fields and levels are a syntactic flag associated withloci. In general, a syntax flag is a string of tags that represent avalid syntactic position. Syntax flags can be used in connection withmacro-tags comprising micro-tags, such as in a bar code. In variousembodiments, flags can be associated with an entire syntax and/orcomponents of a syntax.

Anatomic Classification Systems

Anatomic classification systems classify every element of a system asperforming a function which contributes to and can be related to thefunction of the whole system (parts for elements, parts performfunctions for each other and for whole, together facilitate object ofwhole). The function of a system is defined as the process which asystem performs in order to transform the inputs to the system into theoutput of that system. Therefore, the function of a system is defined bythat system's internal 2.2.2 activity.

When the anatomic system is itself an element of a higher-level system,and that higher-level system is also an anatomic system, sets of relatedhierarchical anatomic systems are considered to be nested anatomicsystems. For these nested anatomic systems, the functional relationshipsbetween the hierarchically related anatomic systems can be defined, fromthe lowest-level system to the highest-level system.

For example, three types of nested anatomic systems can be used: nestedmorphological systems, nested physiological systems, and nestedclassification systems. Each type of nested anatomic system can bedefined.

Nested Morphological Systems

Nested morphological systems are anatomic systems which arehierarchically related at multiple levels according to their morphology.A system's morphology is defined as the system's structure. Therefore,when two systems are hierarchically related according to theirmorphology, the structure of one system is a constituent part of thelarger structure of the other system. It therefore follows that thefunction which the lower-level system performs is also one of thefunctions which the higher-level system performs. Therefore, the twosystems are anatomically related. For example, the informationprocessing function of a semiconductor contributes to the informationprocessing function of a computer.

The classification system described herein defines the structure of asystem by its subject resource (which may represent a set of subjectresources). Therefore, when two or more systems are morphologicallyrelated, the subject resource of one system is a constituent part of thesubject resource or set of subject resources of the other system.Accordingly, nested morphological systems can be classified as differentoperating levels: subordinate resource level, final resource level, workgroup level, departmental level, and company and consumer level.

Nested Physiological Systems

Nested physiological systems are anatomic systems which arehierarchically related at multiple levels according to their physiology.A system's physiology is defined as the processes or activities whichthe system performs. Therefore, when two systems are hierarchicallyrelated according to their physiology, the processes of one system are aconstituent part of the larger-scale processes performed by the secondsystem.

The function of a system can be defined as the process whereby thesystem converts inputs into outputs; and that therefore the function ofa system is defined by that system's internal 2.2.2 activity. When twosystems are physiologically related, the process which a lower-levelsystem performs (its internal 2.2.2 activity) is a component part of theprocess which the higher-level system performs (the internal 2.2.2activity of the higher-level system). Therefore, by definition, thefunction of the lower-level system is a component part of the functionof the higher-level system; and the two systems are thus anatomicallyrelated. For example, a 4.2.1 consulting function contributes to the4.2.2 management function of a company.

While different operating levels have physiological relationships (inaddition to their morphological ones), physiological relationships canbe classified as relating to the processes performed by departments,divisions, phases, and cycles. Departments perform processes which areconstituent parts of divisions, divisions perform processes which areconstituent parts of phases, and phases perform processes which areconstituent parts of cycles.

The physiological relationships between departments, divisions, phasesand cycles are expressed by the outputs and objects of these systems. Inother words, the output (object) of a department reflects its ownoutput, as well as the output of its division, phase and cycle.Therefore, nested physiological systems can be classified by identifyingmultiple objects (direct and indirect) for a given locus. In this case,the indirect object of the department classified by the locus reflectsthe direct object of that department's phase. That phase isphysiologically related to the department classified.

Nested Classification Systems

The system can include four levels of anatomically-relatedclassification systems: elements (resources, stages, and activities),loci, fields, and company classification system (in its entirety). Thefunction of each classification system is to classify some attributerelating to the company being classified. This function contributes toand can be related to the function of a higher-level classificationsystem—namely the classification of a larger-scale set of attributesrelating to the company. Therefore, the system described herein caninclude a series of nested anatomic systems, in which the classificationsystems at every level perform a classification function whichcontributes to the classification function of a classification system ata higher-level. Therefore, all four levels of classification systems areanatomic systems.

Classifying Morphological and Physiological Systems

Morphologically and physiologically related systems can be classifiedwithin a tiered structure as follows:

At level 1—the elements classification level, when resource stages areclassified;

At level 3—the fields classification level, when loci are classifiedinto fields by relating the loci in those fields based on theiroperating (morphological) level;

Physiologically related systems are classified at the following levelsof classification:

At level 2—the loci level, when the direct and indirect objects of alocus are classified. The direct object of a locus refers to the objectof the department. The indirect object of a locus refers to the objectof that department's phase.

Coordinate System

A coordinate system assigns attributes to the elements of a system inorder to determine the relative positions and order of those elements inthe system. The coordinate systems described herein can share thefollowing characteristics:

1. A common denominator according to which increments between theelements of the system can be measured, compared, and differentiated.The denominators of time, level, importance, or mechanical role can beused. All coordinate systems have a common denominator according towhich increments between the elements of the system can be measured,compared, and differentiated. As described herein, four types ofdenominators are used for coordinate-based systems:

Time (also known as “sequence” or “sequential”): classifying actions inthe activity cycle, classifying loci into fields, classifying fieldsinto the whole company classification system;

Morphological Level: classifying resource stages, classifying loci intofields;

Importance: classifying loci into fields;

Mechanical Role (also known as functional role): classifying resourcesinto resource categories.

2. A fixed reference point for the elements of the system. This fixedreference point can be either a) an element of the system, b) ahigher-level classification system of which that system is a part, or c)an element external to that system. All coordinate systems have a fixedreference point for the elements of the system. Tree types of fixedreference points can be identified:

a) When the elements of a system are anatomically related based on theirmorphology or physiology, the elements of that system are classifiedwith reference to the highest-level morphological or physiologicalelement of the system.

Resource Stages: the 12 resource stages with which resources areclassified are anatomically related based on their morphology.Therefore, the resource stage coordinate values have a fixed referencepoint of their highest-level coordinate value: stage 4.

Loci related by morphological levels: Loci defining a subordinateresource, final resource, work group, department, and company areanatomically related based on their morphology. Therefore, levelcoordinate values have a fixed reference point of their highest-levelcoordinate value: the locus classifying the company or consumer in whoseoperations the other loci function.

Activity Cycle: the 2.2.2 activity of the internal activity cycle of anysystem is at the same time that activity which the system as a wholeperforms in order to produce its product. In other words, this 2.2.2activity, in addition to being a part of an activity cycle, alsooperates at a higher level than the other activities of that cycle.Therefore, the non-2.2.2 activities of an activity cycle are classifiedwith reference to the 2.2.2 activity of that cycle.

b) When the elements of a system are not anatomically related based onmorphology or physiology, the same coordinate values which are used forthe system elements to an anatomic system which contains those elementscan be applied, then the elements of that system with reference to thatsuperior anatomic system classified.

Resources: No one final resource is at a higher level than another finalresource. However, the mechanical role of the work group in which thosefinal resources are used can be classified. Resources with reference tothe contribution which the final resources of their respectivecategories (A, B, C, D, E, F) make to the function and operation oftheir work group can be classified, which is the anatomically superiorsystem (by morphology) in which those resources are used.

Loci related by importance: When two loci are related by their relativeimportance to the field in which they operate, neither locus operates ata higher morphological or physiological level than the other locus.However, which locus is more important can be defined with reference tothe field in which they operate. The relative importance of these locican be classified with reference to the contribution which they make tothe field in which they operate. This field is an anatomically superiorsystem (by classification) in which these loci are classified.

c) When the elements of a system are not anatomically related based onmorphology or physiology, and it is not possible to define thecoordinate values of those elements in relation to similar coordinatevalues of a superior system, then the elements of that system can beclassified with reference to an element which is external to that system(not in that system).

Temporal relationships between loci: When two loci are temporallyrelated, neither locus operates at a higher morphological orphysiological level than the other locus.

The temporal relationship between these two loci can be classified withreference to an element which is not classified by either locus butwhich is instead acted on or influenced by the activities specified inboth loci.

When the two enterprise loci, the two intermediary loci, or the twocustomer loci are temporally related, they are so related with respectto when the activities specified in both loci interact with thecompany's product.

Temporal relationships between fields: Similarly to temporalrelationships between loci, fields are defined with reference to theirtemporal interaction with the company's product. There is also afunctional relationship.

3. A directional reference which defines the order of values accordingto the common denominator. A directional reference which defines theorder of values according to the common denominator.

Time: When the relationship between elements of a system is based ontime, then the temporal order of these elements (first, second, third)can be defined with respect to some fixed reference point.

Morphological Level: When the relationship between elements of a systemis based on morphological level, the hierarchical order of theseelements can be defined from lowest-level (least complex) tohighest-level (most complex). Lower-level elements always perform afunction to enable the function and operation of the higher-levelelements.

Importance: When the relationship between elements of a system is basedon importance, then which element is the most important (primary), whichelement is the next most important (secondary), etc. can be defined.

Mechanical Role: Resources are first classified as either operational orenabling resources according to their function, and are then classifiedin the order of 1) foundational, 2) mechanical, and 3) neural.

Anatomic Coordinate System

An anatomic coordinate system is an anatomic system which is definedusing coordinate values. As a result, every element in the systemperforms a function which contributes to and can be related with thefunction of the system as a whole. Each element in the system has valuesassociated with it which define the position and order of each elementin the system.

Because classification systems at each of the four levels are anatomic,the classification of elements, fields, and the whole companyclassification system—since they are coordinate-based—are by definitionanatomic coordinate systems:

Elements: resources, stages, and activities—anatomic coordinateclassification systems

Loci: anatomic word classification systems which are notcoordinate-based

Fields: anatomic coordinate classification systems

Word Classification System

A word classification system groups words based on linguistic categoriessuch as nouns and verbs into expressions and sentences. The elements ofthe system—the nouns, verbs, adjectives and adverbs—have functionalmeanings and values associated with their grammatical position in theexpression or sentence. As described herein, level 2 (loci) is ananatomic word classification system, because the classification systemapplies grammatical values to the elements of the system—resources andactivities—in order to order them into a locus, or sentence.

Defining the Levels of Classification

An overview of classification levels is provided below.

A customer locus will have four coordinate values which uniquelydetermine its syntactic position:

Level: Company-level

Importance: Primary (or secondary)

Time: Second (or first)

Field: Customer Field

Similarly, an enterprise locus will have four coordinate values:

Level: Company-level

Importance: Secondary (or primary)

Time: First (or second)

Field: Enterprise Field

A product locus will have only 2 coordinate values, because there isonly 1 locus operating at that level:

Level: Subordinate Resource Level (or final resource, work group, ordepartmental level)

Field: Customer Field

The levels are defined with respect to how anatomic coordinates are usedto classify loci into fields.

The classification system is a nested anatomic classification systemconsisting of four levels. How to apply the different types ofclassification systems at each of these four levels is described below.The four levels of classification are:

1. Elements: Resources, Stages, and Activities. These elements can beclassified by using an anatomic coordinate system based on the commondenominators of mechanical roles, levels, and time, respectively.

2. Loci: Elements can be classified into loci using a wordclassification system by defining the grammatical roles of elementswithin those loci.

3. Fields: Loci can be classified into fields by using an anatomiccoordinate system based on the common denominators of time, importance,and level. These anatomic coordinates are expressed both by the valuesand sections of the loci within their field, and by the relationshipmarkers assigned to those loci. Fields define the largest groupings ofloci which can be defined and ordered by these three types of coordinatevalues.4. Company Classification System: Fields can be classified into thewhole classification system by using an anatomic coordinate system basedon time.

Based on these definitions, it is possible define for each of the fourfields how to organize loci by using the anatomic coordinates of time,importance, and level. In doing so, it is possible to definerelationship markers as expressing these coordinate values.

Classification Level 1: Resources

The first level of classification is the classification of resources,resource stages, and activities. The resource classification systemclassifies all resources used in the economy with six resourcecoordinate values. The resource system can be represented as an anatomicsystem, because each element of the system performs a function whichcontributes to and can be related to the function of the whole system.

Elements: The elements of a resource system are the resources used asthe subjects of a work group. These resources are classified with sixresource coordinate values. Each resource coordinate value is defined asperforming a specific type of function for the whole resource system.

Whole System: The whole resource system consists of all subjectresources used in a work group and can include at least one resource ineach of the six coordinate values.

Functions can be related: The resource system can be represented as ananatomic system because the functions of each of the elements—as definedby the 6 coordinate values—contributes to and is related with thefunction performed by the full set of subject resources, which is toperform the work of that work group.

The resource system can be represented as a coordinate system becauseeach resource used in a work group is assigned one of six attributeswhich determines the relative position and order of those resourceswithin the work group: A (real estate), B (equipment), C (information),D (money), E (energy), and F (labor).

The common denominator for resource coordinate values is mechanicalrole. Each of these six coordinate values is associated with a specifictype of function which a resource classified with that coordinate valueprovides to the work group in which it operates. These six mechanicalroles are: A) passive structure; B) physical work; C) directives; D)financing; E) power; and F) initiation of all physical andinformation-based work. Note that in addition to functional role, A) andB) are also differentiated by whether they are fixed-in-place ormoveable.

Resource coordinate values can have a fixed reference point in the workgroup. Resources are classified with reference to the contribution whichthe final resources associated with each of the 6 resource coordinatevalues make to the function and operation of their work group.

In some embodiments, the directional reference of resource coordinatevalues can be 1) structural, 2) mechanical, and/or 3) neural. In otherwords, based on the common denominator of mechanical role the structureand environment necessary to perform the action of a work group proceedsthe physical force of the action, which proceeds the ongoing monitoringand control of that action.

Resource Stage Classification System: The resource stage classificationsystem classifies all resources (with the exception of F) used in theeconomy with 12 resource stage coordinate values. The Resource StageClassification System is an anatomic system, because each element of thesystem performs a function which contributes to and can be related tothe function of the whole system.

Elements: The elements of a resource stage classification system are thestage values used to define the morphological level of the resourcewhich are classified. By definition, a resource classified with a givenstage value is a component part of a resource with a higher-level stagevalue and performs a function which is one of the many functionsperformed by the higher-level resource.

Whole System: The whole system consists of all resource stages whichcollectively compose a final resource. The whole system can include atleast one level-1 stage value and one level-4 stage value, and mayinclude up to all twelve resource stage values.

Functions can be related: The resource stage system is an anatomicsystem because the function performed by a resource with a lower-levelstage value contributes to and is related with the function performed bya resource with a higher-level stage value, and ultimately with thefinal resource itself.

The resource stage system can be represented as a coordinate systembecause all resources are assigned 1 of 12 attributes which determinesthe morphological level of a given resource within a final resource. Thecommon denominator for resource stage coordinate values is morphologicallevel. Each of the 12 coordinate values is associated with a specificmorphological level relative to a final resource. Resource stagecoordinate values have a fixed reference point in the final resource.Resources can be classified with stage values which define themorphological level of that resource relative to the final resource inwhich it operates.

The directional reference of resource stage coordinate values is “up” or“down”. In other words, when moving from a resource with a lower-levelstage value to a higher-level stage value, one moves “up” in terms ofmorphological level, and vice versa one moves “down” when one moves froma resource with a higher-level stage value to a resource with alower-level stage value.

Classification Level 1: Activities

Activity Classification System: The activity classification systemclassifies all actions performed in the economy with 36 activitycoordinate values. The Activity Classification System is an anatomicsystem, because each element of the system performs a function whichcontributes to and can be related to the function of the whole system.

Elements: The elements of an activity classification system are the 36activity values which every company and person can perform. If aneconomic system does not have a full internal activity cycle (forexample, work groups and resources), then the activity system of thateconomic system is defined as consisting of all internal activitiesperformed by that economic system. In other words, an activity systemmay not contain all 36 coordinate values.

Whole System: The whole activity system consists of all 36 activitiesand defines the function which all 36 activities collectively perform.This function is defined by the 2.2.2 activity of the system. Companiesand people have a whole activity system.

Functions can be related: The activity classification system isanatomical, because the functions of all elements classified with the 36activity coordinate values is to enable the functionality of theactivity cycle as a whole—in other words, the 2.2.2 activity which atthe same time represents the process of the whole activity system.

The activity system can be represented as a coordinate system in thatactions are assigned 1 of 36 attributes which determines the temporalrelationship and functional role of a given action within its activitysystem (activity cycle). The common denominator for activity coordinatevalues is time. Each of the 36 coordinate values is associated with aspecific temporal position relative to the other actions of the cycle.

Activity coordinate values have a fixed reference point in that the2.2.2 activity of that system. Actions with activity values which definethe temporal relationship of that action can be defined relative to the2.2.2 activity of the system, because the 2.2.2 activity defines theprocess which the higher-level system performs in order to produce itsoutput.

In some embodiments, the directional reference of activity values can beforward. In other words, the activity coordinate values are temporallyordered such that a given action temporally proceeds another action witha higher activity coordinate value. Time can be sequentially ordered.

Classification Level 2: Loci

The second level of classification is the classification of resourcesand activities into loci. The classification system can be an anatomicsystem, because each element of the system performs a function whichcontributes to and can be related to the function of the whole system.

Elements: The elements of a locus classification system are resources(and their stages) and activities.

Whole System: The classification system can include a subject resource(optional), activity, direct object, and indirect object (optional). Inthis system, each resource and activity element performs a functionalrole. Functions can be related and the classification system can beanatomical because each element (resource and activity) has a definedgrammatical role which contributes to the function defined by the locusas a whole.

A word classification system groups words based on linguistic categoriessuch as nouns and verbs into expressions and sentences. Therefore, theclassification of resources and activities into a locus is a wordclassification system, because resources and activities are defined asnouns and verbs, respectively, and assign these nouns and verbs valuesdependent on their grammatical position within the locus.

A locus has four grammatical positions: Subject Resource(optional)-Activity-Direct Object-Indirect Object (optional). Byassigning one of these four positions within the locus to a resource oractivity, the function of that resource or activity is defined relativeto the other resources and activities in the locus, and to the locusitself.

Classification Level 3: Fields

The third level of classification is the classification of loci intofields. A field is defined as a system of loci in which the positionsand identity of the loci within that field are uniquely determined bythese three types of coordinate values. The field classification systemclassifies loci into fields by using three types of coordinate values:

Level: defines the morphological level at which a locus operates;

Time: defines when a locus operates relative to a fixed reference point;

Importance: defines the relative importance of a locus based on itscontribution to the function of the field in which it is classified.

A field is defined as a system of loci in which the positions andidentity of the loci within that field are uniquely determined by thesethree types of coordinate values. The size of a field can be determinedby defining it as consisting of all loci which can be related to eachother with these three types of coordinate values. Therefore, for agiven field, all the loci in a given field can be related to each otherby using these three types of coordinate values: morphological level,time and importance.

Using these criteria, four fields of loci can be identified:

Enterprise Field: defines the operations of the company classified.

Intermediary Field: defines the operations of the intermediaries of thecompany classified.

Customer Field: defines the operations of the customer or customerswhich use the company's product, and the function and use of the productwithin the operations of the most important customer.

Customer of Customer Field: defines the operations of the customer ofcustomer which uses the customer's product, and the function and use ofthe customer's product within the operations of the customer ofcustomer.

Three types of coordinate values can be used to order loci into fieldsare defined in more detail. These four fields can be defined in moredetail and both 1) the names and order of the loci and 2) relationshipmarkers can be used to define the 3 types of coordinate values for eachfield.

Within a field, the horizontal axis is based on the coordinate values oftime and importance and the vertical axis is based on morphologicallevels. The position and identity of the two enterprise loci within theEnterprise Field is entirely determined by:

Importance: the enterprise locus which contributes more to the functionof the Enterprise Field is labeled “primary” and the other locus“secondary”;

Time: with reference to the company's product, the enterprise locuswhich operates first is labeled “first” and the other locus “second”;

Level: both enterprise loci operate at the company level. Thiscoordinate value therefore provides important information but does notdifferentiate them.

Therefore, each enterprise locus can be provided three coordinate valuesof importance, time, and level, which uniquely identify the two lociwithin the field.

The position and identity of the two intermediary loci within theIntermediary Field is determined by:

Importance: the intermediary locus which contributes more to thefunction of the Intermediary Field is labeled “primary” and the otherlocus “secondary”;

Time: with reference to the company's product, the intermediary locuswhich operates first is labeled “first” and the other locus “second”;

Level: both intermediary loci operate at the company level. Thiscoordinate value therefore provides important information but does notdifferentiate them.

Therefore, each intermediary locus can be provided three coordinatevalues of importance, time, and level, which uniquely identify the twoloci within the field.

With respect to the customer field, the horizontal axis can be based onthe coordinate values of time and importance and the vertical axis isbased on morphological levels. The positions and identities of the sixloci within the customer field can be determined by the three coordinatevalues of:

Level: at which of the 5 morphological levels does the locus operate;

Importance: when there is more than 1 locus at a particular level, whichlocus is more important. This applies to the company level, where twocustomer loci are identified. Importance can be “Primary” or“Secondary.”

Time: when there is more than 1 locus at a particular level, which locusis performed first with reference to some fixed reference point. Thisapplies to the company level, where two customer loci are identified.The reference point can be the company's product. Time can be “First” or“Second.”

With respect to the customer of customer field, the horizontal axis canbe based on the coordinate values of time and importance and thevertical axis is based on morphological levels. The positions andidentities of the six loci within the customer field are entirelydetermined by level coordinate values:

Level: at which of the five morphological levels does the locus operate.

Importance: because there is only one locus at a given level, n/a.

Time: because there is only one locus at a given level, n/a.

Classification Level 3: Levels

“Level” Coordinate Values: define the morphological level at which eachlocus in a given field operates. Five morphological levels can beidentified, in ascending order: Subordinate Resource Level, FinalResource Level, Work Group Level, Departmental Level, Company andConsumer Level.

The Level Classification System is anatomic, because each element of thesystem performs a function which contributes to and can be related tothe function of the whole system.

The elements are the loci classified at the different morphologicallevels. The system is the highest-level locus in which operations thelower-level loci are classified, and all the loci identified asoperating in that highest-level locus. A lower-level locus performs afunction which contributes to and is related with the functionsperformed by the higher-level loci in whose operations that locusoperates.

Level-Based Coordinate Values

Because every locus can be specified as operating at one of these fivelevels, level coordinate values can be applied to every locus in everyfield. However, because the “Level” Classification System iscoordinate-based, three characteristics can be defined:

A Common Denominator according to which increments between the elementsof the system can be measured, compared, and differentiated. Thedenominator here is the level at which the locus operates. A locus canbe classified according to this denominator by defining the locus asoperating at one of the five levels listed.

A Fixed Reference Point for the elements of the system. The fixedreference point here is the higher-level classification system of whichthat system is a part. Note that simply classifying a locus at one ofthe five levels does not necessarily define this fixed reference point.

A Directional Reference which defines the order of values according tothe common denominator. This directional reference is defined byordering these five levels from lowest to highest.

By labeling each locus with one of the five level values, 1) the commondenominator and 3) the directional reference can be defined, but 2) afixed reference point is not necessarily defined.

Defining the Fixed Reference Point

The fixed reference point for a level-based classification system is thehighest-level locus (company, consumer) in which a locus operates. Inother words, even though multiple fields may contain loci which have thesame level coordinate value (subordinate resource, final resource . . .), the loci in different fields will have different fixed referencepoints, because the company or consumer in whose operations the locusoperates will be different.

For example, a departmental locus can be classified in both thecustomer's operations and the customer of customer's operations. These 2loci have the same level-based coordinate value—the department—but theyhave different reference points: the customer and the customer ofcustomer, respectively.

In some embodiments of the classification system, seven loci can beidentified which classify companies or consumers:

2 Enterprise Loci

2 Intermediary Loci

2 Customer Loci

1 Customer of Customer Locus

These 7 loci are therefore the fixed reference points for thelevels-based coordinate system. In some cases, no more than 1departmental, work group, final resource, or subordinate resource locuswithin the operations of any of these 7 loci are identified. Therefore,in that classification system, simply stating the highest-level locus asthe reference point is sufficient to uniquely map every locus. Note thatfor these 7 loci, they are their own reference points, in addition tohaving a company or consumer level as their coordinate value. Inaddition, 1 fixed reference point may be sufficient for when jobs areadded (which would be a final resource within an enterprise locus).

Theoretical Application of Level-Based Coordinates

In some cases it is possible to identify two or more loci at the samemorphological level within the same company's or consumer's operations.In this case, it would be necessary not only to specify thehighest-level company or consumer as the reference point, it would alsobe necessary to specify an immediate higher-level locus as a referencepoint to distinguish the two loci.

For example, if two final resources within 1 company's operations areclassified, then the two final resources may be used within differentwork groups, in which case by referencing the different work groups thelevels-based coordinate values of these 2 loci could be differentiated.Note that if the two final resources were used in the same work group,then they would operate as part of the same work group set of subjectresources and would then have the same levels-based coordinate values.

Classification Level 3: Time

Temporal Coordinate Values define the temporal relationship between 2 ormore loci operating at the same level in the same field. The coordinatevalues of: First, Second, Third, etc. could be used.

The Temporal Classification System is anatomic, because each element ofthe system performs a function which contributes to and can be relatedto the function of the whole system. The elements are the lociclassified with the different temporal coordinate values. The wholesystem includes all the loci which are temporally related to the samefixed reference point. In order for the locus with the “Second” temporalcoordinate to perform its function, the locus with the “First” temporalcoordinate can perform its function, and similarly for loci labeled“Third,” “Fourth,” etc. In other words, the functions of each of theloci has a defined temporal relationship with the function of each ofthe other loci with the same temporal reference point. Therefore, thefunctions of each locus to each other can be related, and ultimately tothe functions represented by all of the loci temporally related whichcompose this temporal classification system.

Temporal Coordinate values. When more than 1 locus is classified asoperating at the same morphological level within a given field, thoseloci can be differentiated by applying temporal (and alsoimportance-based) coordinate values. Using only multiple loci at thelevel of companies and consumers, temporal coordinate values can beapplied to this company-level. Therefore, temporal coordinate values canbe used to relate:

The two Enterprise Loci as First and Second

The two Intermediary Loci as First and Second

The two Customer Loci as First and Second

Because the classification of loci into systems of temporally relatedloci is coordinate-based, 3 coordinate-based characteristics can bedefined: The Common Denominator is time. The Directional Reference isforward, as time moves from the locus labeled “first” to the locuslabeled “second”. The Fixed Reference Point is an element external tothe system of temporally-related loci. In other words, this referencepoint is not one of the related loci or the system consisting of thoseloci. This fixed reference point can be defined as the company'sproduct. Therefore, the 2 enterprise loci, 2 intermediary loci, and 2customer loci can be temporally related by defining when the 2 loci ofeach field interact with the company's product. The way in which theseloci interact with the product is determined by the field in which theloci operate. The nature of these interactions for each field can bedefined.

Enterprise Loci

If both enterprise loci acts on the same resource-product of thecompany, then given a resource-product, that enterprise locus whichfirst acts on that product will be classified with the temporalcoordinate of “First”, and that enterprise locus which acts second onthat product will be classified with the temporal coordinate of“Second”. If one enterprise locus has a resource-product, and oneenterprise locus has an activity-product; or if both enterprise locihave an activity-product, then the company offers the two productscreated by the 2 enterprise loci in conjunction with one another.

In this case, the temporal coordinates of the 2 enterprise loci ban bebased on when the primary customer uses their products. For a givencombination of the 2 products, that enterprise locus which produces theproduct which the primary customer first uses is classified as the firstenterprise locus, and that enterprise locus which produces the productwhich the primary customer uses last is classified as the secondenterprise locus.

Therefore, in both cases, the enterprise loci can be classified withreference to the fixed reference point of the product. However, thedifference is in the relationship of the enterprise loci to the product:in the first case, when the enterprise loci act on the same product; inthe latter case, when the primary customer uses the combinationproducts.

Intermediary Loci

The 2 intermediary loci can be classified with temporal coordinatesbased on when they first interact with the company's product. If anintermediary takes ownership of a product, then the time when it firsttakes ownership of the product can be defined to be when it firstinteracts with that product. If an intermediary does not take ownershipof a product, then the time when it first acts on that product can bedefined to be when it first interacts with that product. Therefore, fora given company's product, that intermediary which first takes ownershipof or acts on the company's product is classified in the firstintermediary locus; and that intermediary which next takes ownership ofor acts on that same product is classified in the second intermediarylocus.

Customer Loci

In some cases, there may be only two customer loci when two customersinteract with the company's product (parallel customers). When thecompany is an intermediary, the company which sells the product beingintermediated naturally is classified as the first customer; whereas thecompany or consumer which buys the product is classified as the secondcustomer.

Note that this is not synonymous with “importance”. For example, for abroker which represents the buyer, the first customer is the seller andthe second customer is the buyer. However, by order of importance, theprimary customer is the buyer and the secondary customer is the seller.When the company is not an intermediary, then broadly speaking the firstcustomer pays for the product, and the second customer uses the product.

Theoretical Application of Temporal Coordinates

The system can be used to differentiate loci using temporal coordinatesat the level of companies and consumers. When temporal relationshipbetween 2 loci in a field can be specified by referencing a fixedelement, then temporal coordinates can be defined for those 2 (or more)loci. These loci do not have to operate at the same level.

A temporal relationship can be defined between the work group locus andthe departmental locus by referencing the A4ii building. When thetemporal relationship between the work group and the department isdefined as when the loci interact with the building, either by acting onit or using it in the operations of the locus, then the work group canbe defined as temporally coming before the department. In other words,the work group can be defined as “first” or temporally proceeding thedepartmental locus, the “second” locus.

In this expanded application of temporal coordinates, multiple loci donot need to be related at the same morphological level, rather loci atdifferent morphological levels can be temporally related. In thisexpanded application, a given locus may have more than 1 temporalrelationship: not only at its same morphological level, but to a locuswhich is superior or subordinate to it by level. In other words, lociwhich are related to each other based on their morphological level maytemporally come before or after each other. They may also operate at thesame time, which is the usual case for product loci.

Loci operating at different levels would operate at different timesprimarily when the work group locus and departmental locus are different(when the work group acts on a subject resource used in the department).In some embodiments, this application of temporal coordinates mayobviate the need to add an additional morphological level.

Classification Level 3: Importance

Importance-based coordinate values define the relative importance of 2or more loci operating at the same level within a given field. Thecoordinate values are labeled as: Primary, Secondary, Tertiary, etc.

The Temporal Classification System is anatomic, because each element ofthe system performs a function which contributes to and can be relatedto the function of the whole system. The elements are the lociclassified with the different importance-based coordinate values of“primary”, “secondary” . . . . The whole system includes the loci whichare related based on their relative importance, in some cases, all lociat a given morphological level within a field. Importance-basedcoordinate values define the relative contribution of the functionsperformed by the loci at a given level to the overall functionalityperformed by that entire morphological level in the field. Theimportance-based classification system is therefore an anatomic system,because the functions performed by the elements—the loci—can be relatedto the function performed by the whole system—all the loci operating atthat same morphological level in the field.

As a non-limiting example, the primary enterprise locus and thesecondary enterprise locus are the 2 elements of the classificationsystem consisting of both loci. The primary enterprise locus performsmore of the functionality associated with the enterprise loci than doesthe secondary enterprise locus.

As a non-limiting example, the primary intermediary locus and thesecondary intermediary locus are the 2 elements of the classificationsystem consisting of both loci. The primary intermediary locus performsmore of the functionality associated with the intermediary loci thandoes the secondary intermediary locus.

As a non-limiting example, the primary customer locus and the secondarycustomer locus are the 2 elements of the classification systemconsisting of both loci. Note that this classification system does notinclude the whole customer field, but only those 2 loci which operate atthe same morphological level—the company-level—and which can be relatedin terms of their relative importance. The primary customer locusperforms more of the functionality associated with the company-level ofthe customer field than does the secondary customer locus.

Coordinate Values

Because the “Importance-based” Classification System iscoordinate-based, the system has the following 3 characteristics:

A Common Denominator according to which increments between the elementsof the system can be measured, compared, and differentiated. Thedenominator here is importance.

A Fixed Reference Point for the elements of the system. The fixedreference point here is the higher-level classification system of whichthat system is a part: the entire morphological level in a specificfield consisting of all the loci related by relative importance.

A Directional Reference which defines the order of values according tothe common denominator. This directional reference is defined by ourordering the relative importance of these loci into primary, secondary,and possibly tertiary values.

Classification Level 4: Whole Company Classification System

Anatomic Classification System

The 4 fields—enterprise field, intermediary field, customer field, andcustomer of customer field—can be classified within the whole companyclassification system. The classification of the 4 fields—EnterpriseField, Intermediary Field, Customer Field, and Customer of CustomerField—into the whole company classification system is an anatomicclassification system: The elements of the classification system are the4 fields and the whole system consists of all 4 fields.

The function of the whole company classification system is to classifythe company within the economy by defining a series of standardizedattributes relating to that company. The function of 1 field is toclassify a series of attributes relating to one aspect of a company'sbusiness, and these attributes contribute to and constitute a componentpart of the classification system as a whole. Therefore, therelationship of these 4 fields to the whole company classificationsystem is anatomic.

Temporal Coordinate Classification System

The 4 fields are temporally related, so that:

The Enterprise Field first interacts with the company's product bymaking or providing that product. Therefore, with reference to a givencompany product, every enterprise locus temporally comes before everyother locus in the other field.

The Intermediary Field next interacts with the company's product eitherby purchasing and reselling the product or acting on it to enable it tobe sold. Therefore, with reference to a given company product, everyintermediary locus temporally comes after every enterprise locus andbefore every locus in the customer and customer of customer fields.

The Customer Field interacts with the company's product by purchasing itand using it in the customer's operations. Therefore, with reference toa given company product, every locus in the customer field temporallycomes after every intermediary locus and before every locus in thecustomer of customer field.

The Customer of Customer Field interacts with the company's product byusing the customer's product, which was a result of the originalcompany's product being used in the customer's operations. Therefore,with reference to a given company product, every locus in the customerof customer field temporally comes after every other locus in the other3 fields.

However, even though these four fields are temporally related, thistemporal relationship is not coordinate-based. If a company isclassified with at least one locus in each of the four fields, then thefields would be temporally ordered:

Enterprise Field: First, Intermediary Field: Second, Customer Field:Third, Customer of Customer Field Fourth. However, a company isclassified with no Intermediary Field and no Customer of Customer Field,then the fields would be ordered:

Enterprise Field: First, Customer Field: Second.

Therefore, fields do not have defined temporal coordinate values.

A locus can be defined as having a unique position in a field based onthe 3 coordinate values of time, importance, and level.

The field value of a locus to uniquely determine its position in thewhole classification system, the only option is to assign each locus a4th coordinate value specifying in which of the 4 fields the locusoperates: Enterprise Field, Intermediary Field, Customer Field, Customerof Customer Field.

Differentiating Business Information

Information can be used as a marker for each unique activity performedby a business. Labor could be differentiated and located in theirappropriate place in the system.

Generalizable Model of an Eco-System

An economic system is a systems of cooperative activities (and theirstructural elements) among members of a species that provide for andmaintain the elements used by the specific species to live their lives.In some cases, economic systems can be considered to be sub-systems ofan ecological system, operating under the same functional rules andenvironmental constraints as each sub-system that provides for andmaintains the macro-ecological system in which they all exist andoperate.

Labor Systems

The systems of cyclical activities (and their structural elements) thatprovide for and maintain the elements that provide the labor in aneconomic system. It is believed that rules by which labor works are thesame as the rules by which each upper level ecological system operates.

Some of the basic terms may be defined:

Work: Any activity performed in an economic system.

Job: The functional objective of work by a resource in an economicsystem.

Labor: The functional objective of work by a member of a species in aneconomic system.

Activities may be characterized as nodal or connecting. Connectingactivities are situated between nodal activities. Attributes can beassigned to each role. In some embodiments, these attributes can beconstant throughout the system.

The system can be configured to include different types of authorizingand connecting roles. In authoritative roles, there can be: 1) the actof signing and 2) the act of validating. In connecting roles, there canbe: 1) entrance activities and 2) exit activities.

The authoritative and connecting roles may be further characterized as“originating” or “following.” The roles can be considered to a 36-partsystem, illustrated by a wheel, as in FIG. 5. The characterizations asoriginating or following can be further divided into primary, secondary,or tertiary.

Through color, shape and number, the tags provide role markers for eachactivity. These role markers explain an activity's role or function in aparticular operation. The avatars explain what an activity actually doesin performing its role. The different types of activities, at differentlevels, can be assigned predetermined colors and symbols. The symbolscan enable specific activities to be marked, tracked and compared.

The number scheme can be used to place or locate activities in thesystem. The role markers explain the role of each location in theoverall system. With reference to FIG. 5, using numbers, avatars androle markers, each activity can be differentiated. These parametersindicate an activity's: 1) location; 2) functional job; and 3)functional role.

For example, each system has an internal 36-Part (sequence) set ofoperating activities. Each sequence in each system has a common role.Together, these common sequential roles produce specific output. Theactual activities performed in each part will depend on: (1) Theintended product of the specific system, (2) The resources available atthe time, (3) The macro-environment in which the activity is beingperformed, and (4) The macro-environment from which the system came.

These 36 distinct roles exist at each level. Every system in aneco-system has these same distinct 36 roles. In every system, specificactivities will differ depending on the system.

Other Examples

The functional information system described herein could be used inpredictive modeling, functional positioning, positional operatingdashboards, risk management, as well as functional location awarenessand cross-system comparisons.

Genetics

It may prove helpful to examine locus/loci/locale terminology as used ingenetics—in particular it may be useful as a test of the extent to whichthe Locus Technology patent is capturing a sufficiently generalabstraction to accommodate a gene database.

FIS—The Macro-Economy Overview:

A key benefit of any coordinate information system is the ability toaggregate data for the whole system or any subset. In addition,coordinate information systems provide the ability to compare analogouscoordinate sub-sets. This ability to aggregate data systematically basedon underlying coordinate values is a valuable benefit of anycoordinate-based system such as a GIS System or an FIS System.

A Functional Positioning System (FPS):

A key benefit of any coordinate information system is the ability to goto a specific coordinate and view the information stored at the specificcoordinate. Once an application puts a user at a specific coordinate, italso lets the user see and/or interact with the other coordinate valuearound the specific coordinate. This “Around Me” functionality is verycommon in GIS Systems for both Business and Weather Applications. Thisability to examine whole systems on a point by point basissystematically based on underlying coordinate values is a valuablebenefit of any coordinate-based system and is embodied in PositioningSystems like GPS Systems or an FPS Systems.

FIS-Risk Management:

A coordinate system has unique values associated with every coordinate.In operations each coordinate has different risks associated with it.The ability to identify, quantify and manage risks associated with eachcoordinate is enabled with a coordinate information system.

GIS Systems are used as the basis for risk management in many domains. Awell-known example is insurance. Geo-coordinates a statisticallyrelevant with respect to weather and national disasters. GIS Systems arethe backbone of insurance companies that deal in insurance associatedwith these areas.

FIS-Accounting:

Accounting programs all use customer supplied chart of accountsorganized by customer designated nominal departments. An FIS systemwould enable arrangement of the departments, work groups and jobs in away that was consistent between levels and constant across companies.

FIS-City Planning

An FIS Cities application would enable cities to compare themselves toother cities. This would enable them to identify peer cities andclusters, to compare their coordinates with other cities and tounderstand how their city operated as a whole city.

FIS-Corporate Strategy/Business Plan Development:

An FIS system has the capabilities of providing a lab or workbook typeenvironment where a customer could do plan evaluation, plan developmentand plan modeling. This could all be done in the context of otheranalogous commercial systems.

FIS-Human Resources:

A key benefit of a coordinate based system is the ability to comparecoordinate values on one level to coordinate values on another level.Human resources is an excellent example where that is valuable. Each jobhas coordinate values on one level. Each enterprise has coordinatevalues on another level. A functional FIS system would let a user mapsspecific jobs to specific enterprises. For a given type of company, thesystem would enable a user to compare the composite of employees withineach company.

FIS-Job Training

A key benefit of a functional coordinate system is the ability is thefact that every coordinate is defined. Every coordinate is populatedwith information relevant to the specific coordinate. Form a trainingperspective this enables a customers to train its employees about eachjob, its responsibilities and how it fits in the overall operations.This would be very valuable to any company and to any current employeeand any prospective employee.

FIS-Time and Space:

Every action happens at specific time at a specific space. This is truefor any action that takes place at a functional coordinate. That is tosay, any functional activity happens at a functional location at aspecific time at a specific space. An FIS System adds a new coordinatebased location to the temporal location and spatial locations thatinformation systems use. Developing tools that enable a user to set eachof these three coordinate-based variables independently would be helpfulon many levels. It would enable users to fix any one of the variablesand see how its values vary as one or more of the other variables arechanged. One could take farming as a functional coordinate. The toolwould let the user examine how farming varies by geography and varies bytime. A user could examine when were the transforming breakthroughs intechnology.

Using geo-coordinates, many companies have built global informationsystems that populated each geo-coordinate with geo-location basedinformation. For each longitude, latitude or elevation there are largedatabase that contain information related to these values. Thesedatabases also adapt as a user navigates these coordinates. As you driveyour rental car down a highway the information fed to your car based onyour location changes. This is because your car is accessing one of themany global geographic information systems that have been built over thelast few decades. If you subscribe to one of these services they willprovide you specific information for any geo-coordinate filtered the wayyou need: e.g.; restaurants, gas stations, intersections, or weather toname a few. This is the benefit of these global geo-informationdatabases. Once built, the application world has seemingly no end in thenumber of useful “aps” based on these systems and a user's specificlocation in the system.

The systems disclosed herein can be used to build a global functionalinformation system. Each functional coordinates will be populated withcoordinate specific information. Like its GIS counterpart, once built,the application world will also have seemingly no end in the number ofuseful “aps” based on these systems and a user's specific location inthe system. An important one will be this ability to integrate with thealready built geo-coordinate information system and thetemporal-coordinate information system in a way that would enable a userto navigate all three simultaneously.

System Architectures

The systems and methods described herein can be implemented in softwareor hardware or any combination thereof. The systems and methodsdescribed herein can be implemented using one or more computing deviceswhich may or may not be physically or logically separate from eachother. Additionally, various aspects of the methods described herein maybe combined or merged into other functions.

In some embodiments, the illustrated system elements could be combinedinto a single hardware device or separated into multiple hardwaredevices. If multiple hardware devices are used, the hardware devicescould be physically located proximate to or remotely from each other.

The methods can be implemented in a computer program product accessiblefrom a computer-usable or computer-readable storage medium that providesprogram code for use by or in connection with a computer or anyinstruction execution system. A computer-usable or computer-readablestorage medium can be any apparatus that can contain or store theprogram for use by or in connection with the computer or instructionexecution system, apparatus, or device.

A data processing system suitable for storing and/or executing thecorresponding program code can include at least one processor coupleddirectly or indirectly to computerized data storage devices such asmemory elements. Input/output (I/O) devices (including but not limitedto keyboards, displays, pointing devices, etc.) can be coupled to thesystem. Network adapters may also be coupled to the system to enable thedata processing system to become coupled to other data processingsystems or remote printers or storage devices through interveningprivate or public networks. To provide for interaction with a user, thefeatures can be implemented on a computer with a display device, such asa CRT (cathode ray tube), LCD (liquid crystal display), or another typeof monitor for displaying information to the user, and a keyboard and aninput device, such as a mouse or trackball by which the user can provideinput to the computer.

A computer program can be a set of instructions that can be used,directly or indirectly, in a computer. The systems and methods describedherein can be implemented using programming languages such as Ruby™,Flash™, JAVA™, C++, C, C#, Visual Basic™, JavaScript™, PHP, XML, HTML,etc., or a combination of programming languages, including compiled orinterpreted languages, and can be deployed in any form, including as astand-alone program or as a module, component, subroutine, or other unitsuitable for use in a computing environment. The software can include,but is not limited to, firmware, resident software, microcode, etc.Protocols such as SOAP/HTTP may be used in implementing interfacesbetween programming modules. The components and functionality describedherein may be implemented on any operating system or environmentexecuting in a virtualized or non-virtualized environment, using anyprogramming language suitable for software development, including, butnot limited to, different versions of Microsoft Windows™, Android™,Apple™ Mac™, iOS™, Unix™/X-Windows™, Linux™, etc. The system could beimplemented using a web application framework, such as Ruby on Rails.

The processing system can be in communication with a computerized datastorage system. The data storage system can include a non-relational orrelational data store, such as a MySQL™ or other relational database.Other physical and logical database types could be used. The data storemay be a database server, such as PostgreSQL™, MongoDB™, Microsoft SQLServer™, Oracle™, IBM DB2™, SQLITE™, or any other database software,relational or otherwise. The data store may store the informationidentifying syntactical tags and any information required to operate onsyntactical tags. In some embodiments, the processing system may useobject-oriented programming and may store data in objects. In theseembodiments, the processing system may use an object-relational mapper(ORM) to store the data objects in a relational database.

Suitable processors for the execution of a program of instructionsinclude, but are not limited to, general and special purposemicroprocessors, and the sole processor or one of multiple processors orcores, of any kind of computer. A processor may receive and storeinstructions and data from a computerized data storage device such as aread-only memory, a random access memory, both, or any combination ofthe data storage devices described herein. A processor may include anyprocessing circuitry or control circuitry operative to control theoperations and performance of an electronic device.

The processor may also include, or be operatively coupled to communicatewith, one or more data storage devices for storing data. Such datastorage devices can include, as non-limiting examples, magnetic disks(including internal hard disks and removable disks), magneto-opticaldisks, optical disks, read-only memory, random access memory, and/orflash storage. Storage devices suitable for tangibly embodying computerprogram instructions and data can also include all forms of non-volatilememory, including, for example, semiconductor memory devices, such asEPROM, EEPROM, and flash memory devices; magnetic disks such as internalhard disks and removable disks; magneto-optical disks; and CD-ROM andDVD-ROM disks. The processor and the memory can be supplemented by, orincorporated in, ASICs (application-specific integrated circuits).

The systems, modules, and methods described herein can be implementedusing any combination of software or hardware elements. The systems,modules, and methods described herein can be implemented using one ormore virtual machines operating alone or in combination with each other.Any applicable virtualization solution can be used for encapsulating aphysical computing machine platform into a virtual machine that isexecuted under the control of virtualization software running on ahardware computing platform or host. The virtual machine can have bothvirtual system hardware and guest operating system software.

The systems and methods described herein can be implemented in acomputer system that includes a back-end component, such as a dataserver, or that includes a middleware component, such as an applicationserver or an Internet server, or that includes a front-end component,such as a client computer having a graphical user interface or anInternet browser, or any combination of them. The components of thesystem can be connected by any form or medium of digital datacommunication such as a communication network. Examples of communicationnetworks include, e.g., a LAN, a WAN, and the computers and networksthat form the Internet.

One or more embodiments of the invention may be practiced with othercomputer system configurations, including hand-held devices,microprocessor systems, microprocessor-based or programmable consumerelectronics, minicomputers, mainframe computers, etc. The invention mayalso be practiced in distributed computing environments where tasks areperformed by remote processing devices that are linked through anetwork.

While one or more embodiments of the invention have been described,various alterations, additions, permutations and equivalents thereof areincluded within the scope of the invention.

In the description of embodiments, reference is made to the accompanyingdrawings that form a part hereof, which show by way of illustrationspecific embodiments of the claimed subject matter. It is to beunderstood that other embodiments may be used and that changes oralterations, such as structural changes, may be made. Such embodiments,changes or alterations are not necessarily departures from the scopewith respect to the intended claimed subject matter. While the stepsherein may be presented in a certain order, in some cases the orderingmay be changed so that certain inputs are provided at different times orin a different order without changing the function of the systems andmethods described. The disclosed procedures could also be executed indifferent orders. Additionally, various computations that are hereinneed not be performed in the order disclosed, and other embodimentsusing alternative orderings of the computations could be readilyimplemented. In addition to being reordered, the computations could alsobe decomposed into sub-computations with the same results.

What is claimed is:
 1. A method for executing a command in a computingenvironment to perform a database operation utilizing a computerizedrepresentation of a functional system, the method comprising the stepsof: electronically storing a set of data entities in a database system,the data entities representing elements of the functional system,wherein the functional system comprises a group of related elementsordered by their functional roles in converting inputs to outputs, or asthe inputs, or as the outputs; electronically storing a computerizedrepresentation of a functional system syntax, wherein the functionalsystem syntax can be applied by a computer processor to establish thevalidity of expressions of elements of the functional system based onone or more functional attributes of elements of the system; wherein thefunctional attributes are characteristic properties of the elements ofthe functional system, and wherein the elements are electronicallyrepresented by the data entities in the computerized representation ofthe functional information system; wherein the functional informationsystem, utilizing the computerized representation of the functionalsystem syntax, structures the data entities according to functionalrelationships among the inputs, the outputs, and the roles in convertingthe inputs to the outputs; assigning syntactic tags to the data entitiesin the functional information system based on the functional attributesof the elements to which the data entities correspond, thereby enablingdata entities to be combined to form valid syntactic expressions; andenabling data creating, reading, updating, and deleting operations onthe data entities and tags in the data store to correspond with changesin the functional system.
 2. The method of claim 1, wherein: thefunctional system is an economic system, wherein the economic systemcomprises a series of functional activities performed by specificfunctional resources in processes converting inputs into outputs; andthe functional system syntax represents relationships among the elementsof the economic system, wherein the elements comprise inputs, outputs,resources, activities, functions, businesses, enterprises, jobs,sectors, industries, industrial clusters, products, currencies,commodities, imports, or exports.
 3. The method of claim 2, furthercomprising: ordering or grouping the data entities based on theirassociated syntactic tags; performing a relational search based on theassociated syntactic tags; returning a resultant set, the set comprisingdata entities, relationships between the data entities, or values basedon the search; and using the resultant set to analyze a specificdecision process, or impacts, projections, or recommendations associatedwith the process.
 4. The method of claim 1, wherein the functionalsystem is economic, financial, monetary, or fiscal.
 5. The method ofclaim 4, wherein: a resource comprises inputs or outputs in thefunctional system; an activity comprises functions in the functionalsystem; and wherein the elements further comprise one or more resourcesor activities.
 6. The method of claim 5, wherein the resources areselected from capital, energy, information, land, tools, and labor, andthe activities are selected from procurement, transportation, storage,research and development, production, quality control, sales, exchange,banking, investment advisory, management, and audit.
 7. The method ofclaim 5, wherein the valid expressions include loci that can beevaluated by the functional system syntax, wherein each locus comprisestwo or more syntactic tags, one tag representing an activity and one tagrepresenting an output or a resource associated with the activity. 8.The method of claim 1, wherein: the functional system is not economic,financial, monetary, or fiscal; and the functional system is political,chemical, biological, physical, ecological, or mechanical.
 9. The methodof claim 1, further comprising associating non-functional ornon-syntactic geographic or temporal attributes, tags, or values withthe data entities.
 10. The method of claim 1, further comprisingassigning a value to a tag corresponding to at least one of theattributes, wherein the value provides a numerical, statistical,semantic, or visual characterization of a property of an element in thefunctional system.
 11. The method of claim 1, further comprisingperforming the automated assignment of syntactic tags, attributes, orvalues using algorithms based on syntactic tags, attributes, or valuesassociated with the data entities.
 12. The method of claim 1, whereinthe data entities correspond to investment securities, and furthercomprising using the functional system syntax for portfolio management,portfolio construction, index construction, or risk management.
 13. Themethod of claim 1, wherein the expressions, comprising elements, inputs,outputs, or processes, are evaluated by the functional system syntaxaccording to their relationships in the functional system.
 14. Themethod of claim 1, wherein an element is a unit of a lexiconcharacterizing the functional system, and wherein the elements can becombined to form valid expressions according to principles of thesyntax.
 15. A system for executing a command in a computing environmentto perform a database operation utilizing a computerized representationof a functional system, the system comprising: an electronic data storeconfigured for: electronically storing a set of data entities in adatabase system, the data entities representing elements of thefunctional system, wherein the functional system comprises a group ofrelated elements ordered by their functional roles in converting inputsto outputs, or as the inputs, or as the outputs; electronically storinga computerized representation of a functional system syntax, wherein thefunctional system syntax can be applied by a computer processor toestablish the validity of expressions of elements of the functionalsystem based on one or more functional attributes of elements of thesystem; wherein the functional attributes are characteristic propertiesof the elements of the functional system, and wherein the elements areelectronically represented by the data entities in the computerizedrepresentation of the functional information system; wherein thefunctional information system, utilizing the computerized representationof the functional system syntax, structures the data entities accordingto functional relationships among the inputs, the outputs, and the rolesin converting the inputs to the outputs; and a computerized processorconfigured for: assigning syntactic tags to the data entities in thefunctional information system based on the functional attributes of theelements to which the data entities correspond, thereby enabling dataentities to be combined to form valid syntactic expressions; andenabling data creating, reading, updating, and deleting operations onthe data entities and tags in the data store to correspond with changesin the functional system.
 16. The system of claim 15, wherein: thefunctional system is an economic system, wherein the economic systemcomprises a series of functional activities performed by specificfunctional resources in processes converting inputs into outputs; andthe functional system syntax represents relationships among the elementsof the economic system, wherein the elements comprise inputs, outputs,resources, activities, functions, businesses, enterprises, jobs,sectors, industries, industrial clusters, products, currencies,commodities, imports, or exports.
 17. The system of claim 16, whereinthe computerized processor is further configured for: selecting,ordering, or grouping the data entities based on their associatedsyntactic tags; performing a relational search based on the associatedsyntactic tags; returning a resultant set, the set comprising dataentities, relationships between the data entities, or values based onthe search; and using the resultant set to analyze a specific decisionprocess, or impacts, projections, or recommendations associated with theprocess.
 18. The system of claim 15, wherein the functional system iseconomic, financial, monetary, or fiscal.